JP4757865B2 - Uplink packet transfer channel scheduling method in wireless communication system - Google Patents

Abstract

A method of scheduling an uplink packet transmission channel in a mobile communication system is disclosed. The method of scheduling includes determining a scope of user equipments (UEs) to be applied to a scheduling assignment for scheduling the uplink packet transmission channel (S32, S34), and transmitting the scheduling assignment to the user equipments included in the determined scope (S33, S35, S36), wherein the scheduling assignment includes an identifier for identifying the scope of the user equipments and scheduling contents for carrying information applicable to the scheduling assignment. Preferably, said scope of user equipments is determined by the status of the uplink packet trasmission channel (S31) and according to the determined scope the scheduling assigment is either transmitted to each UE (S33), to a group of UEs (35) or to all UEs (36).

Description

  The present invention relates to a radio packet communication system, and more particularly, to an uplink packet scheduling method in a radio packet communication system. The present invention can be applied to various cases, and in particular, can be applied to a case where scheduling information is transferred to a specific group subscriber or an entire subscriber.

  In a wireless packet communication system including a mobile communication system, a discussion on a high-speed packet communication method in an uplink in which data is transmitted from a terminal to a base station in response to a request for an increase in uplink speed and capacity increase Has been made actively.

  A representative example thereof is the E-DCH (Enhanced Up Linked Channel) technology discussed in the 3GPP WCDMA wireless mobile communication system.

  In the E-DCH technology, technologies such as uplink packet scheduling by the base station (Node B) and HARQ (Hybrid ARQ) in the physical layer are introduced into the existing 3GPP WCDMA uplink DCH (dedicated channel) to improve uplink efficiency. Try to improve. In particular, the system processing rate can be improved by efficiently configuring each scheduling command during base station (Node B) scheduling.

  One technique applicable to the existing 3GPP WCDMAE-DCH is a base station controlled scheduling (Node B controlled scheduling) method. According to the standardization progressed to date, the channel for transferring base station scheduling instructions will use time division multiplexing (TDM), code division multiplexing (CDM) or time and code division multiplexing ( Similar to HSDPA). In this case, the scheduling command transferred to each terminal (User Equipment: UE) basically includes UE classification information (terminal ID) and scheduling contents.

  The terminal investigates a downlink link channel used for scheduling command transfer, and if it is confirmed that the scheduling command is transmitted to itself by the terminal ID, the terminal acquires scheduling contents and acquires the acquired scheduling. Start, interrupt, or reserve the transfer according to the content instructions. As described above, since the scheduling command is individually transferred from the base station to each terminal, a large amount of time and channel are required even when the same scheduling information is transferred to a specific group of terminals or all terminals.

  That is, as described above, the scheduling command is individually transmitted to each terminal by time division, code division, or time and code division scheme.

  In conclusion, there is a problem in transferring an urgent scheduling command to a specific terminal group or an entire terminal in the physical layer (Layer 1) dimension. In addition, when such an individual terminal transfer method is used, congestion may occur due to a rapid increase in uplink traffic in the physical layer dimension, and it is difficult to deal with such cases quickly. It was.

  The present invention presents an uplink packet transfer channel scheduling method in a wireless communication system for solving at least one problem associated with the limitations and disadvantages of the prior art.

  An object of the present invention is to provide an uplink packet transfer channel scheduling method in a base station of a wireless communication system.

  It is another object of the present invention to provide a method for scheduling an uplink packet transfer channel in order to effectively solve the communication congestion problem.

  It is still another object of the present invention to provide a method for scheduling an uplink packet transfer channel for transferring a scheduling command not only to individual terminals but also to a specific terminal group and all terminals.

  As an aspect of the present invention for achieving the above object, an uplink packet transfer channel scheduling method at a ground station is provided. In the uplink packet transfer panel scheduling method, a range of terminals that receive a scheduling command for uplink transfer channel scheduling is determined. Furthermore, the received scheduling command is transferred to terminals included in the determined range. Further, the scheduling command includes terminal ID information for identifying the range of the terminal and scheduling contents for transmitting information corresponding to the scheduling command.

  As another aspect of the present invention, an uplink packet transfer channel scheduling method for an individual terminal is provided. In the uplink packet transfer channel scheduling method, a terminal receives a scheduling command transferred from a base station. This scheduling command includes terminal ID information for identifying a range of terminals for the scheduling command. In addition, the scheduling command includes scheduling content for transmitting information corresponding to the scheduling command and scheduling content for transferring a packet through the uplink packet transfer channel according to the scheduling command.

  According to the present invention, the base station determines whether or not to allow packet transfer in consideration of the channel condition, and notifies the terminal of the problem. It is possible to relax and improve the efficiency of the entire system.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals and numbers are commonly used as much as possible to the same components.

  Although the preferred embodiment of the present invention has been described in connection with an E-DCH (Enhanced Uplink Dedicated Channel), the present invention is applicable to any wireless packet communication system.

  In order to transfer a scheduling command to an individual terminal, the base station (Node B) uses an E-AGCH (Enhanced Absolute Grant Channel) downlink channel. That is, the base station transfers the command so that each terminal transfers at an allowable transfer power or transfer data rate level. Hereinafter, this command is also referred to as an uplink scheduling command or a scheduling command.

  In the E-AGCH, each frame used in downlink transfer for a scheduling command of a base station includes a terminal identifier (ID) and scheduling contents. The terminal ID is used to identify a terminal that receives a scheduling command for the uplink packet transfer.

  This scheduling content includes various information such as scheduled power, duration, and priority. Here, the scheduled power information (also referred to as 'rate') is defined as the maximum amount of power that can be allocated for transfer in uplink packet transfer. The duration information represents how long the effective scheduling command for each terminal lasts. The priority information means a specific restriction on uplink packet transfer. For example, in the case of expressing the priority of transfer in order from the alphabet A, if the base station transfers the scheduling command to the first terminal with the priority of C, the first terminal transfers at the transfer time of the first terminal. In other words, the first terminal transfers at the time when the terminal having the C priority order transfers. In addition, each scheduling command may include any combination of the above information such as terminal ID, scheduled power and priority, or terminal ID, scheduled power and interval.

  In E-AGCH, a base station can transfer a scheduling command to an individual terminal, a terminal belonging to a specific group, or an entire terminal via a shared channel. Terminals sharing these channels receive and decode the transferred scheduling command. After the reception and decoding, the scheduling command is performed by the terminal having the corresponding ID according to the terminal ID information included in the transfer packet of the scheduling command. For example, it is assumed that there are four terminals, a first terminal to a fourth terminal. In this case, the base station (Node B) transfers the scheduling command to the four terminals via the shared channel. The scheduling command will be for the first terminal only. All these four terminals receive and decode the scheduling command and identify which terminal the scheduling command is for. The transferred scheduling command packet includes terminal ID information corresponding only to the first terminal. Therefore, the scheduling command is performed only by the first terminal. This is also applicable to terminal groups.

  Also, in E-AGCH, each terminal can have one or more terminal identifiers. Each terminal includes an identifier corresponding to a scheduling command for each of these terminals and another identifier corresponding to a scheduling command transmitted by another terminal that has received the initial scheduling command transferred from the base station. That is, it includes not only the terminal identifier for following the scheduling command transferred from the base station, but also the other terminal identifier for following the scheduling command transmitted by other terminals sharing the channel. By transmitting the scheduling command, the amount of channel transfer between the base station and the terminal can be reduced and minimized. The number of identifiers that one terminal can have is not limited to the above-described two types of identifiers, and may have more according to various purposes.

  More specifically, for example, when the terminal receives and decodes the scheduling information for the fourth terminal transferred from the base station, the fourth terminal transmits all the terminals sharing the channel (ie, the first terminal). The terminal, the second terminal, the third terminal, and the fourth terminal) are instructed to transmit the scheduling command. At this time, the scheduling command is not transmitted from the base station but from another terminal that has received the initial command. When the scheduling command transmitted from the fourth terminal is received, all the other terminals sharing the channel receive and decode the command in the same manner as when the command is received from the base station. Here, the scheduling command identifies the first terminal, the second terminal, and the fourth terminal to perform. When each terminal includes another terminal identifier, the base station instructs a scheduling instruction for a plurality of terminals to one terminal, and the terminal transmits the scheduling instruction to the other terminals, thereby causing the same scheduling to be performed. Instruction transfer can be minimized.

  Unlike E-AGCH, E-RGCH (Enhanced Relativistic Grant Channel) has a transfer channel already set by the base station, and transfers the scheduling command via this channel. In E-RGCH, the scheduling command consists of at least one bit, and the terminal ID is not included in the transfer packet information. Specifically, a terminal that receives a scheduling command through a channel that has already been set reads and executes the command. For example, assume that there are four terminals, a first terminal to a fourth terminal. The base station transfers the scheduling command applied only to the first terminal only to the first terminal. Since the transfer channel has already been set, the scheduling command is not transferred to other terminals.

  In the E-RGCH, the scheduling command is not limited to be transferred to only one terminal at a time. That is, multiple channels for transferring the same scheduling command for multiple terminals may already be set up. To explain this example, if the base station has already set the first channel and the second channel respectively to transfer the same scheduling command to the first terminal and the second terminal, the same scheduling command is sent to other terminals ( It is not transferred to the third terminal and the fourth terminal) and is transferred only to the first terminal and the second terminal. Only the first terminal and the second terminal receive and execute the scheduling command.

  As explained above, the difference between E-AGCH and E-RGCH is clear. In the case of E-AGCH, all terminals sharing the channel receive the scheduling command regardless of the terminal to which the scheduling command is directed. However, the scheduling command is applied only to a terminal having an ID corresponding to the ID specified by the scheduling command. In the case of E-RGCH, a transfer channel is set in advance by the base station, and only a terminal corresponding to the already set channel receives the scheduling command. A terminal that has not been set by the base station does not receive the scheduling command.

  An embodiment of the present invention will be described in more detail in connection with E-AGCH as follows. The base station (Node B) uses the scheduling allocation channels Ch-1 to Ch-n to transfer the scheduling command to the terminal (UE) by code division, time division, or code and time division combination method. The scheduling command includes scheduling contents and a terminal ID of an individual terminal, a terminal ID of a specific group, or an ID that can be received by the entire UE. Specifically, the scheduling content is content that the base station scheduler instructs each terminal, and may include content such as packet transfer power (Tx_Power), TFC (Transmit Format Combination), and packet transfer time. As described above, the terminal ID is an identifier for identifying the terminal or group to which the scheduling command is transmitted.

  The operation of the base station for determining the scheduling command transferred to the terminal will be described. The base station (Node B) grasps the state of the uplink channel to which the packet is transferred at every transmission time interval (TTI) of the scheduling command. As methods for grasping the situation of the uplink channel, there are signal-to-noise ratio (Signal-to-Noise Ratio: SNR), signal-to-noise-interference ratio (Signal-to-Interference-plus-Noise Ratio: SINR), and thermal noise. Received signal power (Rise over Thermal: RoT) can be used. Hereinafter, a case where the channel status is grasped using RoT will be described. That is, the base station determines the RoT value by grasping the state of the uplink channel. The determined RoT value is compared with an already set critical value. The critical value is set so as not to exceed the maximum RoT value allowed in the communication system. Depending on whether the determined RoT value exceeds a preset threshold value, whether to schedule to an individual terminal, a specific group terminal, or an entire terminal is determined. Although a single critical value is used in the above example, multiple critical values may be used in determining how to transfer scheduling instructions. Furthermore, as described above, the method for determining the uplink channel status is not limited to RoT, and other methods may be used.

  Hereinafter, a scheduling method for setting two critical values (RoTth1, RoTth2, where RoTth1 ≧ RoTth2) will be described as an example with reference to FIG.

  The base station determines a RoT value for each transmission time interval (TTI: Transmit Time Interval) of the scheduling command (S31). This RoT value can be determined by calculating the power of the received signal with respect to the thermal noise of the base station. The RoT value is determined, and the determined RoT value is compared with RoTth1 (S32). The RoT value usually corresponds to noise / interference. When the noise / interference is low, since the thermal noise compared with the received signal power is small, the RoT value is determined to be large. On the other hand, if the noise / interference is high, since the thermal noise compared with the received signal power is large, the RoT value is determined to be small. If the determined RoT value is greater than or equal to the RoTth1 value (RoT ≧ RoTth1), this means a low noise / interference situation, and a scheduling command is transferred to each terminal (S33). When the scheduling command is transferred, the receiving terminal is determined by the terminal ID, and the receiving terminal transfers a signal according to the scheduling content.

  If the determined RoT value is smaller than the RoTth1 value, the determined RoT value is compared with the RoTth2 value. Since it has been determined that the determined RoT value is smaller than the RoTth1 value in the previous step, the base station (Node B) determines whether the determined RoT value is greater than or equal to the RoTth2 value. (RoTth2 ≦ RoT <RoTth1) (S34). That is, when the determined RoT value is smaller than the RoTth1 value and larger than or equal to the RoTth2 value, the scheduling command including the terminal ID and the scheduling content is transferred to at least one specific terminal group (S35). The specific terminal group ID can be used by the terminals included in the group to identify the scheduling command specified for the specific group, and can be set in advance between the base station and the terminal by various methods. it can.

  When the determined RoT value is smaller than RoTth2 (RoT <RoTth2), this means a low RoT value due to a high noise / interference situation, and constitutes scheduling information and ID information that can be received by all terminals. One scheduling command may be transferred to all terminals in the cell, and the scheduling content may be applied to all terminals in the cell (S36). The method using the RoT value is one of various methods for determining the uplink channel status, and as the other method, the above-described SNR, SINR, or the like can be used.

  FIG. 1 shows a number of scheduling assignment channels between different time frames for each channel. Here, each channel can transfer a scheduling command for an individual terminal in addition to a scheduling command for a specific terminal and a scheduling command for all terminals. That is, different types of scheduling instructions are transferred at different times.

  Referring to FIG. 1, Ch-1 to Ch-n refer to orthogonal variable spreading factor (OVSF) code channels used to transfer scheduling instructions. In particular, 'n' represents the number of terminals that can be decoded simultaneously. Further, SAi (i = 1 to n) is a scheduling command transferred to the i th individual terminal, and SA-Gi (i = 1 to k) is designed to be transmitted to the terminals in the i th group. The scheduling instruction SA-all means a scheduling instruction designed to be transmitted to all terminals.

  FIG. 2 is a diagram illustrating a state in which a scheduling command is transferred to terminals included in a large number of terminal groups or to all terminals. As described above, the scheduling command determined by the base station based on the noise / interference of the uplink packet transfer channel controls the uplink packet transfer.

  Referring to FIG. 2, the base station transfers a scheduling command to n terminals included in a specific group indicated by SA-G1 and SA-G2. At the same time, the scheduling command can be transferred to the whole terminal as instructed by SA-all. The scheduling command includes a specific terminal ID indicating the specific terminal group or the entire terminal and the scheduling content and is transferred.

  It is also possible to transfer the scheduling command to the entire terminal using a separate channel from the channel used to transfer the scheduling command to a specific group of terminals or to each individual terminal.

  The scheduling command can include information related to packet transfer permission or prohibition. In other words, the base station decides whether to allow packet transfer in consideration of the channel status and informs the terminal, thereby mitigating problems such as unnecessary congestion on the channel and lack of resources. The efficiency of the system can be improved.

  It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit and essential characteristics of the invention. Accordingly, the scope of the invention is defined by the appended claims and their equivalents, and all changes within the scope of the invention should be construed as belonging to the present invention.

It is a figure which shows the scheduling allocation channel allocated with the time-axis. It is a figure which shows the scheduling allocation channel grouped. 6 is a flow diagram illustrating a procedure for determining how to transfer a scheduling instruction.

Claims (18)

A method for scheduling an uplink transport channel at a base station, comprising:
A scheduling allocation (SA) including a field indicating the maximum amount of power for uplink packet transfer is transmitted to the terminal (E-AGCH (Enhanced-Absolute Grant Channel))
To the UE), and
Receiving an uplink data packet transferred based on the maximum power amount through an E-DCH (Enhanced-uplink Dedicated Channel);
Including
The scheduling assignment (SA) may further include a second identifier for a plurality of terminals including a first identifier or the terminal to said terminal, both of the first identifier and the second identifier, the terminal the E-AGCH Scheduling method, characterized in that it is assigned to the terminal to receive the scheduling assignment above .   The scheduling method of claim 1, wherein the scheduling allocation further includes a scheduled power command for maximum power allocation for the uplink packet transfer.   The scheduling method according to claim 2, wherein each UE of the E-AGCH shared channel has at least one UE identifier. Determining a state of the E-DCH;
Determining whether the scheduling assignment is associated with the plurality of UEs according to a state of the E-DCH;
The scheduling method according to claim 1, further comprising:   The scheduling method according to claim 4, wherein the state of the E-DCH is determined as a function of a RoT (Rise over Thermal noise) value.   The scheduling method of claim 1, wherein the scheduling assignment further comprises a transfer priority command associated with the E-DCH.   The scheduling method according to claim 1, wherein the scheduling assignment further includes an instruction for granting or denying transfer of the E-DCH. Transferring the scheduling assignment comprises:
Further comprising transferring the scheduling assignment to the plurality of UEs through a shared channel of the E-AGCH;
The scheduling method according to claim 1, wherein the scheduling assignment is received and decoded by each of the plurality of UEs. A method for scheduling an uplink packet transfer channel for a terminal (UE) comprising:
The UE assigns a scheduling allocation (SA) including a field indicating a maximum power amount for uplink packet transfer based on a first identifier for the UE and a second identifier for a plurality of UEs according to E-AGCH (Enhanced-Absolute Receiving from the base station via Grant Channel),
Transferring an uplink packet through E-DCH (Enhanced-uplink Dedicated Channel) based on the maximum amount of power;
Including
The scheduling assignment (SA) may further include a second identifier for the first identifier or the plurality of UE to the UE, the UE, the first to receive the scheduling assignment (SA) from the E-AGCH A scheduling method comprising both an identifier and the second identifier.   The scheduling method according to claim 9, wherein the scheduling allocation further includes a scheduled power command for maximum power allocation for the uplink packet transfer. The scheduling method according to claim 10, wherein each UE of the E-AGCH shared channel has two or more UE identifiers.   The scheduling method according to claim 9, wherein the scheduling assignment further includes a transfer priority command associated with the E-DCH.   The scheduling method according to claim 9, wherein the scheduling assignment further includes an instruction for granting or denying transfer of the E-DCH. A terminal (UE) supporting uplink packet transfer channel scheduling,
The UE scheduling assignment includes a field that indicates the maximum amount of power for the uplink packet transfers (SA), E-AGCH, based on the second identifier for a plurality of UE, including the first identifier and the UE for the UE It received from the base station through (Enhanced-Absolute Grant Channel),
On the basis of the maximum amount of power it is urchin configured by to forward the uplink packets through E-DCH (Enhanced-uplink Dedicated Channel),
The scheduling assignment (SA) further includes the first identifier or the second identifier, and the UE receives the scheduling assignment (SA) from the E-AGCH to receive the first identifier and the second identifier . A terminal characterized by having both an identifier.   The terminal of claim 14, wherein the scheduling assignment further includes a scheduled power command for a maximum power allocation for the uplink packet transfer. The terminal according to claim 15, wherein each UE of the E-AGCH shared channel has two or more UE identifiers.   The terminal of claim 14, wherein the scheduling assignment further comprises a transfer priority command associated with the E-DCH.   The terminal of claim 14, wherein the scheduling assignment further comprises an instruction to grant or deny transfer of the E-DCH.

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